A number of embodiments of rotating electrical machines and methods for winding them that provides a high space utilization and very effective winding with less likelihood of damage to the insulation of the wire of the winding during the winding process. The arrangement basically does not require the winding needle to be moved back and forth in the slot between the poles but rather employs insulating inserts that are positioned on the axial faces of the poles outside of the gaps for guiding the wire from one end to the other so as to provide the high space utilization. In one embodiment the insulating insert effectively changes the circumferential length of the coil winding that decreases in an axial direction along their length.
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1. A method of winding the coils of a rotating electrical machine comprising providing a circular core of magnetic material with a plurality of magnetic pole teeth extending radially from the circular core, adjacent pairs of the magnetic pole teeth defining slots formed there between, each of the slots defining a mouth that is formed between adjacent outer ends of the pole teeth, said method comprising positioning a threading needle having an opening through which the wire for the winding of the coils is fed into proximity to one of the mouths, moving the needle opening in a path around one of the pole teeth and at one side of the slot without moving the needle in any substantial distance along the length of the one pole tooth to form a first winding, continuing the movement of the needle opening in a path around the one of the pole teeth at the one side of the slot without moving the needle in any substantial distance along the length of the one pole tooth to form succeeding windings, the circumferential length of the pole teeth decreasing in an axial direction along their length from the opening toward the core, and holding the wire end at the end of the pole tooth spaced from the needle so that each successive winding forces the previous winding along the pole tooth toward the circular core without requiring movement of the needle in any substantial distance into the slot.
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This application is a division of our application, Ser. No. 10/064,362, Filed Jul. 6, 2002, now issued as U.S. Pat. No. 6,831,389 on Dec. 14, 2004, which application is a continuation in part of our application Ser. No. 09/683,764, Filed Feb. 12, 2002, now issued as U.S. Pat. No. 6,590,310 on Jul. 8, 2003, all assigned to the assignee hereof.
This invention relates to a method of making a stator coil structure for a rotating field electrical machine and more particularly to an improved coil method of forming such a device that will provide high efficiency and compact size.
Most rotating electrical machine are comprised of relatively rotatable rotors and stators. One of the rotor and stator carries a plurality of spaced permanent magnets that cooperate with electrical coil windings formed on the other of these members. It is the formation of the electrical coil windings that determines in large part the efficiency of these types of machines. Generally, the winding mechanisms and methods previously proposed have been something less than totally efficient and have at times resulted in very expensive methods and resulting products. This can be best explained by a description of the various types of structures and methods that have been employed for the coil windings. Generally there have been five methods of winding the coils. The first method may be characterized as a “direct winding” method wherein a transverse oscillating system is provided and a winding in the form of an enameled wire is wound around the magnet pole tooth of the core using a needle through which the winding is passed. The winding is wound adjacent the magnetic pole tooth and two upper and lower winding guides slide alternatively between the poles to deposit the windings on them. Alternatively the needle is reciprocated in the slot between the pole teeth and directly winds the wire onto the teeth.
The disadvantage with this type of winding method is that the needle for winding the wire must be placed into the slot from the open end thereof and or the guides must move into this area requiring a dead space between adjacent windings. This restricts the winding density and lowers the space factor thereof. Even when winding guides called formers are employed, the winding lacks alignment and it is difficult to increase the winding density. It is also difficult to apply this method to a stator having a large number of magnetic pole teeth or a revolving field type coil having a small inside diameter. Furthermore, the winding device is complicated in structure and becomes quite large.
When winding guides (formers) are used the resulting rubbing contact with the wire can strip or damage the insulating enamel coating and decrease the electrical efficiency.
In connection with an inner rotor type a stator core is divided into radially protruding portions with a continuous inner periphery and an outer peripheral core is fitted thereon. One way in which this type of device is made is that a coil is wound around a bobbin on the protruded portions. Then the outer peripheral core is fitted after the coil winding. This is called a bobbin winding method. Another way the inner rotor type is made, is that the windings are wound directly on a core having radially protruding sections with an insulating material interposed there between. Then the outer peripheral core is fitted thereon. This is called an outer winding method.
The disadvantages with this second type of construction is that the divided core must be fitted together so that dimensional accuracy is maintained and also to prevent subsequent separation of the parts. Also, the coils must be prevented from bulging out to the outer periphery of the device. This results in complexity in the structure and low production efficiency.
With the bobbin winding method, the winding may deform the bonding flanges and the winding density cannot be enhanced. In addition interference with the outer peripheral core and the dead spaces at the flanges thereof prevent the winding density from being enhanced. In this case, there are deficiencies of lowering the space factor as with the first mentioned method.
A third type of winding method uses divided pole cores. In this case, the armatures are formed as segments, each having a respective pole tooth. Each pole tooth is wound and then the individual segments are fixed together in a suitable manner, normally by welding using a laser beam. This method is not only expensive but raises problems in connection with the dimensional accuracy and the costs involved with the extra steps.
A further method employs what is called a “sawing” method. In this case, a solid core is employed having a plurality of teeth. A needle is passed sequentially through the slots between the magnetic pole teeth in a back and forth sawing motion to wind the winding. This method has the same disadvantages as the first method step described. Also high stresses are placed on the wire that can result in breakage or rupturing of the insulation.
Another method is the so-called “armadillo” type method. In this case, the core is formed in a circular shape and then deformed into a linear shape as used with a linear motor. The winding is then placed on the cores and then the device is again joined by welding the previously cut ends. Again, this method has problems of dimensional accuracy and also because of the stresses exerted on the windings during the successive curving operation, reliability is considerably decreased.
Another type of mechanism for winding employs a needle that is held outside of the slot between the armature teeth at one end of the core and a cam shaped member is provided for reciprocating the winding onto the core. These methods also have considerable disadvantages. In this type of mechanism, the holding and releasing mechanism for the winding is very complicated and the winding action must be repeated during each turn so that rapid productivity is not possible. In addition, the repetition of holding and releasing does not insure good alignment. Even though the needle never enters the slots, a mechanism for introducing the windings into the slots is needed. When this is done, the insulation on the windings may be disturbed.
Thus, the conventional rotating machine presents a problem in that the stator should having windings of a large diameter to permit low voltage and large current to obtain high power. In addition, a large number of magnetic pole teeth are desirable to reduce cogging and to provide smoother rotation and better efficiency. This again results in difficulties in forming the winding.
It is, therefore, a principal object to this invention to provide an improved winding method for coil assembly for a rotating machine wherein accurate coils can be formed having a high density with minimum gaps between the coil windings of adjacent pole teeth.
It is also an object to the invention to provide a method wherein the efficiency of such a machine can be significantly improved.
Our first identified, aforenoted co-pending application discloses a number of embodiments that achieve these objects. However there is still a possibility of obtaining of further advantages. With all of the embodiments therein tapered insert pieces are employed for guiding the Wire toward the opposite end of the pole from the needle. The height of the end of the tapered insert pieces in the area of the needle limits the number of possible windings in this area. Thus maximum winding density is somewhat compromised.
It therefore is a principle object of this invention to provide a method using insert pieces that achieve the objects of our aforenoted application and which offer the possibility of even greater winding density.
This invention is adapted to be embodied in a method of winding the coils of a rotating electrical machine. In this method, a circular core of magnetic material with a plurality of magnetic pole teeth extending radially from the circular core is provided. Each of the magnetic pole teeth defines a core and slots formed there between. Each of the slots defines a mouth that is formed between adjacent outer ends of the cores. The winding method comprises the steps of positioning a threading needle having an opening through which the wire for the winding of the coils is fed into proximity to one of the mouths. The needle opening is moved in a path around one of the pole teeth and at one side of the slot without moving the needle in any substantial distance along the length of the one pole tooth to form a first winding. The movement of the needle opening is continued in a path around the one of the pole teeth at the one side of the slot without moving the needle in any substantial distance along the length of the one pole tooth to form succeeding windings. The circumferential length of the pole teeth decreases in an axial direction along their length and the wire end is held at the end of the pole tooth spaced from the needle so that each successive winding forces the previous winding along the pole tooth toward the circular core without requiring movement of the needle in any substantial distance along the length of the one pole tooth so that the needle not be moved any substantial distance into the slot.
Referring now in detail to the drawings and initially primarily to
The rotating electrical machine 31 is comprised of a stator assembly, indicated generally by the reference numeral 32, and a rotor assembly, indicated generally by the reference numeral 33. These components are contained within a housing assembly that is comprised of a cup shaped, main housing piece 34 and a cover plate 35, which is suitably attached thereto to form an enclosure 36 in which the stator assembly 32 and rotor assembly 33 are positioned.
The rotor assembly 33 is formed with a central portion 37 on which a plurality of circumferentially spaced permanent magnets 38 having alternating polarity are affixed in a known manner. The end portions of the rotor assembly 33 comprise shaft portions 39 and 41 that are journalled, respectively, in bearings 42 carried by an integral closure wall 43 of the cup shaped, main housing piece 34 and bearings 44 carried in a recessed portion 45 of the cover plate 35.
The construction of the rotor assembly 33 may be deemed to be of the general conventional type and any type known in this art might be employed. Also, although the described machine employs an arrangement wherein a coil winding assembly, indicated generally by the reference numeral 46 is provided on individual armature poles, to be described, formed on the stator assembly 32, it should be understood that the coil winding assembly 46 can be mounted on the rotor assembly 33 and the permanent magnets 38 may be mounted as part of the stator assembly including the cup shaped, main housing piece 34.
The stator assembly 32 is comprised of an armature core, indicated generally by the reference numeral 47, which is made up of a plurality of laminated armature plates as shown in
In order to assist in the alignment of the lamination of the core pieces of the armature core 47, each of them is formed with a reference slot 55 on the outer periphery of their circular portion 48. This slot 55 assists in alignment as well as location within the cup shaped, main housing piece 34.
The ends of the slots 54 adjacent the circular portion 48 of the armature core 47 is defined by angularly disposed surfaces 56 formed on opposite sides of the bases of each of the pole teeth 49. These act as projections that cooperate with the projecting ends 52 at the outer ends of the teeth 49 so as to assist in locate an insulating bobbin forming members 57 around which the coil winding assembly 46 is formed as well as locating the individual windings themselves.
Referring now to
As may be seen in
At the outer periphery of the insulator legs 59 and in the area between the slot gaps 53, the insulating bobbin forming member 57 have axially extending flange portions 61. These flange portions 61 are substantially co-extensive with the projecting ends 52 of the armature core portions 51. In addition, an arcuate portion 62 interconnects these axially extending flange portions 61 and extends axially outwardly so as to provide an abutment against which the coil winding assembly 46 will be confined as hereinafter noted. Preferably the arcuate portion has a thickness or height of Sc that is equal to or greater than one half of the width of the slot Sc.
Further projections, indicated at 63, are formed at circumferentially spaced locations around the periphery of the insulating bobbin forming member 57, at least one of which is aligned with the insulator leg portion 59 and another of which is positioned adjacent the intersection between the inclined surfaces 60 as best shown in
In accordance with an important feature of the invention, special insulator inserts indicated by the reference numeral 65 are placed on the faces of the insulator legs 59 on one or preferably both of the insulators in the area between the respective arcuate portions 62 and further projections 63 and 64 thereon. These insulators are shown in lines in
The shape of these insulator inserts 65 may be of any of the configurations shown in
It should be noted that the further projections 63 and 64 need not be formed at the base of each of the pole teeth 49 because of the inclined surfaces 60 formed thereat which will tend to preclude the wire from slipping down along the incline below that point. However, the further projections 63 form a further purpose than stopping the wire coils from slipping down beyond this point as will become apparent.
Referring now specifically to the outer configuration of the various embodiments,
In the embodiment of
It is also not necessary that the curvature extend the full length of the coil winding.
In the embodiments of
Although the various inclined insulator members have been described as separate pieces, they may be detachably affixed to the insulating bobbin forming members 57 or integrally formed thereon.
It has been noted that there is a coil winding assembly 46 formed on the pole teeth 49 of the armature core 47. Although any winding pattern may be employed, a typical winding pattern that can be utilized in conjunction with the invention is shown in
One possible winding arrangement is shown in these two figures wherein each of the phases U, V, and W have their coil windings formed on adjacent poles with a common connection C. Each coil winding is comprised of a forward winding, a reverse winding and a forward winding indicated by the reference characters F, R and F.
As may be seen in
The method by which the winding is accomplished may be best understood and will now be described by reference primarily to
Initially, one end of the wire is clamped by a clamp at the position shown at X in
The needle carrier 71 generally moves in a rectangular pattern around the individual pole teeth 49 and their overlying insulating bobbin forming members 57 as seen in
As the wire is wound, it will be trapped by these edges and will engage the axially outermost portion of the insulator insert 65. Thus, as the needle traverses the path shown by the arrows P in
As each winding is completed, the next winding will engage the previous winding and force it down the incline of the insulator insert 65 so that the wires will collect at the radial outer periphery of the slots 54. There the wire will be restrained by the inclined surfaces 60 of the insulating bobbin forming members 57.
Then, the next series of windings is made and the resulting winding will appear as shown in
Although only one needle carrier 71 and needle 72 is illustrated, preferably several can be provided at circumferentially spaced locations to speed up the winding process. For example there can be provided three of such assemblies, one for each winding phase. They can all be winding at the same time.
It has been noted that one end of the winding is held in the clamp at the position X as shown in
One form of needle and winding method is shown in
In another embodiment, as shown in
It should be noted that the winding method described is very effective in ensuring that the needle or the windings do not engage each other so that the insulation on the individual wires will not be scraped off and good density can be achieved.
This can further be improved by utilizing an insulator, indicated generally by the reference numeral 77 in
In this embodiment, however, the area between the inclined surfaces 60 at the radially outer periphery of the slot 54 is formed with a dividing wall 78. This dividing wall 78 lies in the area where the needle 72 will not pass but nevertheless will hold the wires at the outer periphery of the pole teeth individual leg 59 in separated form so as to result in a winding as shown in
After the desired of the winding methods have been performed utilizing the preferred insulator construction and needle configuration, a controller assembly of any desired type 82 (
The foregoing description includes and was taken from our aforenoted first mentioned co-pending application. As already noted, although those embodiments represent a considerable advance in the art, further improvements are possible.
Referring now to these figures and this added embodiment of the invention, only a section of the stator is shown as the remainder of the machine may be of any type including those previously described. Also where parts are the same as the embodiment of
In this embodiment adjacent coil windings 46 interconnected by crossover wires 66 passed in the slots 54 formed between the pole teeth 51. In this coil structure, the coils 46 are wound around the stator of the three-phase motor having three phases of UVW continuously formed with the coils wound alternately in opposite directions as shown in
For such coils wound alternately in opposite directions, the coils 46 are continuously formed between the adjacent magnetic pole teeth 51 so that the crossover wires 66 are disposed between the coils 46 formed on the adjacent magnetic pole teeth 51. Thus, even if the crossover wires 66 are disposed across the slots 54, the needles are not passed through the slots in winding the coil as described before (
The crossover wires 66 are disposed through the slots 54 in such a manner, whereby there is no need to form a protrusion for hooking a crossover wire as in the previous embodiments so that the insulator structure is simplified and wiring can be easily carried out by saving the crossover wires from being hooked on the protrusions to be disposed in forming the coil. Also, the wiring length becomes shorter, which may result in reducing wiring resistance.
In the above embodiment, the tapered members 65 are used as a wound wire transfer means to slide the windings wound around the protruding end side of the magnetic pole teeth down to its root side without inserting the needle into the slot. However, the coils can also be wound around the magnetic pole teeth from their root sides by using circumference changing members 101 in lieu of such taper members, or by controlling the looping action of the needle to provide slack in the windings as it is drawn out, and thus sliding the windings down to the root sides.
As seen best in
As shown best in
Gradually shortening the circumference in such manner allows a drawing support point of the winding that is drawn out of the needle to be disposed on the outer periphery side and allows the winding to easily slide outward when the winding is wound around the inner periphery side as seen ion
Thus, the drawing support point of the winding drawn out of the needle is located at the bottom of the slot to provide slack in the winding for the needle's winding action, which enables the winding to smoothly slide down to form the coil 46 on the magnetic pole tooth 51 while keeping the height of the circumference changing member 101 constant.
However the upper surface of the circumference changing member 101 may be inclined downwardly toward the bottom side as with the before-mentioned taper members 65. Forming such an inclined surface also enables the winding to slide down to the bottom side as described before. However, forming such an inclined surface makes the height of the circumference changing member on the inlet side of the slot greater, resulting in a large protrusion of the coil ends, and therefore, a greater profile thereof in the radial direction, as aforenoted. With respect to this, keeping the height constant as in the example shown in
Although not necessary, a projection 103 may be formed either on the bobbin 57 at the base of the circumference changing member 101 or on the circumference changing member 101 itself.
Thus, from the foregoing description, it should be readily apparent that the described structures and winding methods provide very dense coil windings and afford very rapid winding methods at a relatively low cost as compared to the prior art constructions and methods. Of course, the foregoing description is that of preferred embodiments of the invention and various changes and modifications in addition to those mentioned may be made without departing from the spirit and scope of the invention, as defined by the appended claims.
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